JPS6362949B2 - - Google Patents

Description

[Detailed Description of the Invention] (a) Field of Industrial Application The present invention provides a simple tracking error correction system for use in 8mm video that records a tracking pilot signal on a video track without forming a control track. Regarding a detection circuit.

(b) Prior art 8mm video records four types of tracking pilot signals on the video track and PCM track instead of the control track.
This enables the DTF servo to control the vertical position of the video head and the ATF servo (capstan servo) to control the tape speed. The DTF servo operates so that the video head correctly scans the center of the track during normal playback, and scans a single track during special playback. The ATF servo also controls the rotational phase of the capstan motor according to the tracking error output obtained by reproducing the tracking pilot signal. For normal VTRs, when performing high-speed playback, the divided output of the playback control signal is used as the comparison signal of the capstan servo, but the tracking error output of the ATF servo for 8mm video is used. used. This tracking error output is used. This tracking error output utilizes four types of tracking pilot signal frequencies, and as shown in FIG. 1, the first to fourth tracking pilot signals are determined. That is, the first signal f ₁ is
102KHz, second signal f ₂ is 118KHz, third signal f ₃ 164K
Hz, and the fourth signal _f4 is set to 148KHz. These signals are cyclically switched at the field period as shown in FIG. 2 and recorded in a superimposed manner on the video signal. When scanning such a track pattern, the difference frequency between the tracking pilot signals recorded on the preceding track and the following track and the tracking pilot signal of the corresponding track is 16 KHz for one and 46 KHz for the other. The scanning position of the video head relative to the track is thus detected by comparing the levels of the 16KHz component, the 46KHz component, and the 46KHz component.

FIG. 3 shows a circuit block diagram of a tracking error detection circuit for normal reproduction. The playback output is
The signal is input to a low-pass filter 1 with a passband of 200 KHz or less, and a reproduced pilot signal containing crosstalk components is derived. This reproduced pilot signal is input to the multiplication circuit 2. An injection signal matching the pilot signal frequency of the corresponding track is input to this multiplier circuit. This injection signal is derived by inputting an RF switching pulse to a 2-bit counter 3 and switching the division frequency of the injection signal oscillation circuit 4 based on the count output. The multiplication output is input to a 16K filter 5 and a 46K filter 6, and the 16KHz difference frequency component and the 46KHz difference frequency component are separately detected. Both detection outputs are input to a comparison circuit 7, their levels are compared, and the comparison output is input to a polarity switching circuit 8. This polarity switching circuit 8 derives a tracking error output by inverting the switching state for each field at the output of a flip-flop 9 which receives the RF switching pulse as input. The reason why this polarity switching circuit 8 must be provided is that the difference frequency components obtained from the preceding or following tracks are inverted for each field.

The tracking error output obtained from the above circuit is used by the DTF servo, which controls the displacement of the video head in the width direction, and the ATF, which controls the tape running.
Used as a servo control signal.

Such a conventional circuit cannot perform tracking control unless the polarity switching circuit 8 is provided. However, this polarity switching circuit 8 must be provided with an inverter and switching means, making the circuit complex and costly.

(c) Purpose Therefore, the present invention solves a simple tracking error with a configuration that eliminates the polarity switching circuit for each field of comparison output by reversing the switching order of the injection signal from the switching order of the reproduction pilot signal. This is a proposed circuit.

(d) Configuration The present invention, as shown in FIG.
When playing back at twice the speed (where m is an integer), the playback pilot signal switches in the forward direction as f ₁ → f ₂ → f ₃ → f ₄ →..., and at (4m - 1) times the speed. When reproducing, considering that the reproduction pilot signal switches in the opposite direction as f ₄ →f ₃ →f ₂ →f ₁ →..., the switching of the injection signal and the switching of the reproduction pilot signal are reversed.

FIG. 5 explains this switching principle. First, when the reproducing pilot signal P ₁ is switched in the forward direction, the 16KHz component F ₁ obtained by following this and switching the injection signal I ₁ in the conventional manner is obtained alternately from the preceding side and the following side. It will be done. However, if the injection signal _i1 is switched in the opposite direction as in the present invention,
The 16KHz component _f1 is always obtained from the preceding truck.

Furthermore, when the reproduction pilot signal _P2 is switched in the reverse direction, if the injection signal _I2 that follows it is input, the 16KHz component _F2 can be obtained alternately, but unlike the present invention, the injection signal i in the forward direction is If you switch ₂ ,
The 16KHz component is uniformly obtained from the preceding track.

Therefore, it is easy to understand that if the injection signal is switched in the reverse order of the switching order of the reproduction pilot signal, the polarity switching circuit that was conventionally required can be eliminated.

The above-mentioned tracking error is explained using the case where a DTF servo mechanism is installed and one track is played back even during special playback, and the tracking error output obtained is based on the DTF servo and
It can be each control input of ATF servo.
However, it goes without saying that even if only the ATF servo is provided, if the tracking error output is averaged, it can be used as the control input for the ATF servo.

(E) Embodiment The present invention will be described below with reference to an illustrative embodiment.

FIG. 5 shows a circuit block diagram of a tracking error detection circuit according to an embodiment of the present invention. The feature of this embodiment is that a reversible counter 3 is used in place of the counter in the conventional circuit.

In this embodiment, when the normal playback or special playback mode is set, the tape runs at a predetermined tape speed. At the same time, the counting mode of the reversible counter 3 is designated according to the tape speed. This designation is made by counting mode designation output D, and 4m
During playback at +1x speed, the high level counting mode designation output D is input and the subtraction mode is activated, resulting in 4m-
During single-speed playback, a low-level counting mode designation output D is input and the addition mode is set. The counter output for counting the RF switching pulses RF is input to the injection oscillation circuit 4 as in the conventional example. The injection oscillation circuit 4 inputs the injection signal to the multiplication circuit 2 in a switching order opposite to that of the reproduction pilot signal. Of the difference frequency components obtained by this multiplication, the 16KHz component and 46KHz component are separated by a 16K filter 5 and a 46K filter 6. this
The 16KHz component is a crosstalk component obtained from the preceding track, and the 46KHz component is a crosstalk component obtained from the following track, so the output of the comparison circuit 7 does not require polarity inversion.

(f) Effects Therefore, according to the present invention, by simply switching the injection signal in the reverse switching order from that of the reproduction pilot signal,
The polarity inversion circuit can be eliminated, and the effect is great.

[Brief explanation of drawings]

Fig. 1 is an explanatory diagram of the tracking pilot signal frequency, Fig. 2 is an explanatory diagram of switching the tracking pilot signal, Fig. 3 is a circuit block diagram of a conventional tracking error detection circuit, and Fig. 4 is an explanatory diagram of the reproduction pilot signal. , FIG. 5 shows a polarity diagram of a tracking error, and FIG. 6 shows a circuit block diagram of a tracking error detection circuit of the present invention. Explanation of main figure numbers 3'...Reversible counter, 4...
...Injection oscillation circuit, 2...Multiplication circuit, 5...16K filter, 6...46K filter, 7...Comparison circuit.

Claims (1)

[Claims] 1. Four types of tracking pilot signal frequencies are switched at the field period so that the difference frequency between the tracking pilot signals before and after switching is alternately 16 KHz and 46 KHz, while the recording track in field units is recorded together with the video signal. In the video tape recorder to be formed, during playback at (4m + 1) times the speed (m is an integer), injection signals are supplied in the reverse switching order to that during recording, and (4m -
1) During double-speed playback, there is an injection oscillation circuit that supplies injection signals in the same order as during recording, a multiplication circuit that multiplies the injection signal and the reproduction pilot signal, and a multiplication output.
A tracking error detection circuit comprising a 16K filter and a 46K filter that separate and derive a 16KHz component and a 46KHz component, and a comparison circuit that compares the output levels of both filters and directly outputs a tracking error.